Pitch control system



Oct 19, 1965 P. E. BARNES ETAL FITCH CONTROL SYSTEM Filed July 50, 1964 United States Patent 3,212,586 PITCH CONTROL SYSTEM Philip E. Barnes, North Granby, and Raymond N. Quenneville, Granby, Conn., assignors to United Aircraft Corporation, East Hartford, Conn., a corporation of Delaware Filed July 30, 1964, Ser. No. 386,254 24 Claims. (Cl. 170-160.24)

This invention relates to a propeller pitch control system and particularly to a system having both hydraulic and mechanical pitch changing means and mechanism utilizing a portion of the mechanical pitch changing means as a mechanical pitch lock.

An object of the invention is mechanism by which the propeller may be feathered after complete failure of the pitch changing motor or its energy source.

Another object is a positive mechanical pitch lock which is immediately effective within about 1 of blade movement.

Another object is a pitch changing mechanism having a feed-back connection from the propeller blade to the control for the pitch changing motor and means utilizing that connection for adjusting the propeller pitch by means of the pitch changing motor, adjusting the propeller pitch mechanically and effecting a pitch lock.

Other objects and yadvantages will be apparent from the following specifications and the attached `drawings in which:

FIGURE 1 is a schematic representation of a structure incorporating the invention.

FIG. 2 is a schematic representation of the governor control mechanism for the pitch control system.

This invention is shown as incorporated in an aeronautical propeller having t'he usual hub 10 mounted on, secured to or integral with a shaft 12 connected with an engine 14 in any suitable well-known manner for driving the shaft and the propeller. The hub supports any desired number of blades 16, although only one is shown for purposes of illustration, in any wellknown manner for pitch changing rotation about an axis extending longitudinally of the blade and for rotating the blades with the hub about the axis of the shaft 12 for providing propulsion. As shown, the blades 16 are supported by ball bearings 18 in the hub 10 for rotation about the pitch changing axis 20. A tube 22 is secured at both ends to the shaft 12 lagainst movement relative to the shaft 12. This shaft is provided with lluid passages and ports for the distribution and control of hydraulic fluid to a pitch changing motor and to a low pitch stop as will be described in more detail hereinafter. The tube 22 is provided adjacent the hub 10 and blade 16 with a piston 24 lixed on the tube. A cylinder 26 closed at both ends surrounds the piston 24 and t0- gether form a pitch changing motor. The end-s 2S and 30 of the cylinder 26 form a Huid tight sliding joint with the exterior of the tube 22 to thereby form a low 'pitch chamber 32 and a high pitch chamber 34 within the piston 26 and separated by the piston 24. Hydraulic fluid under pressure from any suitable and well known source introduced through the supply line 36 and the conduit 38 in the tube 22 may be directed by a movable valve member 40 through either the conduit 42 to the low pitch chamber 32 to move the cylinder 26 in a direction to reduce the propeller pitch or through a channel 44 to the chamber 34 to move the cylinder 26 in the opposite direction to increase the propeller pitch. The cylinder 26 is connected in a well known manner by means of a yoke or cam 46 and a roller 48 with the blade 16 for transforming the linear movement of the `cylinder 26 into a rotary pitch changing movement of the blade 16. The outer circumference of the cylinder ICC 26 forms a lluid tight joint with the inner surface of a cylindrical extension 48 of the hub 10 so as to form a chamber 50 at the end of the cylinder 26. Fluid under pressure is led through the extension 52 of the channel 44 into the chamber 50 at the time it is introduced into the chamber 34 to assist in moving the propeller blades toward high pitch. This additional area is desirable be cause of the inherent tendency -of the propeller blades to reduce their pitch under the inlluence `of centrifugal twisting moments which tendency must be overcome before the blades can be moved toward high pitch.

If desired a low pitch stop may be provided and which may take any suitable for-m. For purposes of illustration, the well known pivoted, retractible stop lingers 54 cooperating with the cylinder extension 56 are used to limit the low pitch movement to a preselected value in the normal operation of the propeller, Introduction of iluid under pressure through line S8 to a chamber 60 will urge piston 62 to the right, from the position shown in the figure maintained -by the spring 64, into contact with the wedge 66 and move the wedge 66 to the right against the action of spring 68 to withdraw the wedge from under the lingers 54 to permit retraction of the ngers 54 and the movement of cylinder 26 to the left beyond the low pitch stop position and into reverse position if desired.

The movable valve member 40 is slidable axially of the tube 22 and cooperates with ports in that tube to selectively direct fluid to the chamber 32 and drain fluid from the chambers 34 and 50 or direct fluid to the chambers 34 and 50 and drain fluid through channels 70 from the chamber 32.

Channel 44 and its extension 52 terminates in a port 72 on the surface of tube 22 and channel 42 terminates in a port 74 on the surface of the tube 22. Channel 38 terminates in a port 76 on the surface of tube 22 and channel 70 terminates in ports 78 and 80 on the surface of the tube 22. The inner surface -of the movable valve member 40 is provided with annular channels or grooves 82 and 84 always in fluid connection with the drain ports 78 and 80. A groove 86 between grooves 82 and 84 is Provided on the interior surface of the movable valve member 40 and is always in lluid flow connection with the ports 76 of the pressure line 38. A land 88 cooperating with port 72 is provided between the grooves 82 .and 86 and a land 90 between the groove 84 and the groove 86 cooperating with the port 74. The movable member 40 has an inoperative or null position as shown in the drawing in which no lluid is fed to or drained from the cylinder 26 or only sufficient fluid is fed to maintain the propeller against any pitch changing movement. The movable member 40 is connected with the cylinder 26 and through a connection formed by the yoke or cam 46 and roller 48 with the blades 16 by a sleeve 92 forming an extension of the cylinder 26. The sleeve 92 terminates in an internally threaded nut 94 cooperating with mating threads lon the exterior of the movable member 40. These mating threads form a helical connection of helical members and provides a feedback from the propeller blades such that any tendency of the blades to move from a position determined by the null position of the movable member 40 will m-ove the member 40 from the null position and return the blades to the selected pitch and the member 40 to the null position.

The movable member 40 is mounted for rotation about the tube 22 and may be rotated by any of the well known mechanisms, such as the single acting governor and double acting motor .and gearing shown in Longfellow et al. Patent No. 2,664,960 or the double acting motor and double acting governor shown in Gaubis et al. Patent No. 3,170,521, for imparting controlled relative r0- tation to two concentric rotating members. For purposes of illustration this mechanism is shown, in this application, as a gear 98 secured to or integral with an extension of the member 40 meshing with a pinion 100 carried by the shaft 12 for transferring motion from the inside to the outside yof the shaft 12. The pinion or pinions 100 mesh with an internal gear 102 having external teeth meshing with a controlled gear 104. A gear 106 fixed on or integral with `shaft 12 meshes with a gear 108 concentric with the gear 104. Gear 108 is connected with the housing 110 of a gear or vane pump or motor 112 and gear 104 is connected with the gear or impeller 105 of the pump or motor. A governor 114 of any suitable type, such as disclosed in Jedrziewski Patent No. 2,636,566 if member 112 is used double actingr or Woodward Patent No. 2,204,640 if member 112 is used single acting responsive to the speed -of the shaft 12 or the engine 14 will drain fluid from or introduce pressure fluid to, or block flow of fluid into or from the pump or motor 112 to rotate the gear 98 in one direction or the other with respect to the shaft 12 or hold the gear 98 against rotation relative to the shaft 12. As shown in FIG. 2, in which the pump or motor 112 is shown as a single acting vane pump or motor for simplicity of showing although it might equally Well be a gear pump orymotor or other single or double lacting positive displacement pump or motor, the single acting pump outlet 107 is connected by line 109 with the control port 111 of the governor 114 and the pump inlet is connected with a reservoir 113. The governor is supplied in the well-known manner with pressure by the pump 115 and drains to reservoir 113 through drain port 117. The governor is supplied with the usual fly weights and speeder spring 121 and governor adjusting means 125. Rotation of the gear 98 and the member 40 in one direction with respect to the shaft 12 and the nut 94 which is fixed against rotation with respect to the shaft 12 and blade support 10 by any suitable means such as splines 95 in a well-known manner such as shown in Gaubis Patent No. 3,153,454 or Barnes et al. Patent No. 3,163,231 will cause the member 40 to be threaded into or our of the nut 94, and move the member 40 in one diricetion longitudinally along the shaft 22 assuming the propeller blade is in a Xed position. Such motion will move the valve member 40 from its null position and also change the relation of the blade pitch and the linear position of said member 40 causing a change in propeller pitch which will restore the valve member 40 again to its null position. Rotation of the gear 98 and the member 40 in the opposite direction will of course translate the valve 40 in the opposite direction along the shaft 22 to thus change the propeller pitch in the opposite direction.

The member 40 is provided with an upstanding flange 116 secured to or formed integral with the member 40. The shaft 12 is provided with a depending flange member 118 secured to or integral with the shaft 12. The inboard face of the depending flange 118 forms or supports one race of a bearing having a roller 120. The other race 122 of the bearing is formed on the end of a sleeve 124 mounted for rotation within the shaft 12. An internal gear 126 is formed on the other end of the shaft 124 and forms part of a planetary reduction gear indicated generally at 128 which terminates in a gear 130. The gear 130 meshes with a series of planets 132 carried by the shaft 12 to bring the drive from the inside to the `outside of the shaft 12. The planets 132 mesh with an internal gear 134 carried by a flange 136. Normally the flange 136 and the race 122 and all the connecting means therebetween rotate as a unit with the shaft including the roller 120 and the depending flange 118.

Upon any failure, accidental or intentional in a wellknown manner such as shown in Britist patent to Charles, Milner and Fairhurst No. 517,372 by opening valve such as valve 123 connecting the pressure line 36 with the drain line 70, of the hydraulic system including the piston 24 or the cylinder 26 or the hydraulic supply source, the centrifugal twisting moment of the blades due to the rotation of the propeller will, through the yoke or cam 46 and roller 48 connection, cause the cylinder 26, the connection 92 and the sleeve 40 to move as a unit bodily toward the left in the illustrated embodiment. Such movement will cause the -upstanding flange 116 to contact the race 122. The depending flange 118 will act as a stop preventing any further movement of the member 40 by the blades 16 after the upstanding flange 116 -contacts the race 122. Flange 116 is normally spaced from the race 122 by an amount substantially equal to or slightly greater than the Width of the port 72 or the land 78 or by an amount slightly greater than the motion required to saturate the valve 40. This clearance may be any desired amount and is normally, relatively small, being substantially the equivalent of about 1 of blade pitch.

Upon failure of the hydraulic system and after the flange 116 has been forced into contact with the blade race 122 the propeller may be turned to a high pitch position or in an increased pitch direction under the iniluence of a rotating or windmilling propeller by means of a brake 138 which may be operated to hold the flange 136 against rotation. Rotation of the propeller will then rotate race 126 and by means of friction between the race 126 and the ange 116, which friction may be augmented by `teeth or friction material if desired, will rotate the flange 116 and the member 40 with respect to the shaft 12, and the nut 94. Rotation of the threaded member 40 inside of the nut 94 Will force the nut 94 along the tube 22 and the shaft 12 and move the propeller blades 16 in a pitch increasing direction to a feathered position where the windmilling will stop and the blade will cease rotating. As long as the brake 138 remains applied, any rotation of the propelled will change the propeller pitch to bring the blades to a feathered position in which there will be no further windmilling. .The flange 136 acts through the reduction gear 128 so as to rotate the blade race and friction element 122 slightly faster than or preferably slightly slower than the rotation of the shaft 12. It will be appreciated that the centrifugal twisting moment of the blades 16 must be sufficient to force the flange 116 to the left with suicient force to provide enough friction between the flange 116 and the blade race 122 to rotate the movable valve member 40 with respect to the shaft 12 and the nut 94. As the propeller blades approach the feathered position and slow down in their rotation the centrifugal twisting moment will be reduced and in order to maintain the frictional contact between the flange 116 and the race 122, Belleville springs which are carried by the nut 40 contact the inturned flange 118 and maintain a load on the flange 116 and the race member 122 which is absorbed through the roller bearing 120.

The operation of the mechanism is as follows: During normal, on speed operation, the input drive gear 102 is held fixed relative to gear 106 and the propeller shaft 12 by the propeller control motor or pump 112. The low ratio gear system 98, 100, 102 holds the screw 96 and the control Valve 40 fixed with respect to the internal parts of the propeller including the tube 22 and its ports. In this position the control valve 40 is in the null position which may be a center position in which it will completely block fluid flow to or from the propeller or may be a position off the center position by an amount sufficient to maintain hydraulic pressure in the high pitch chamber 3:4l sufficient to balance the propeller loads, Iand maintain the propeller blade angle in a fixed or given position.

For overspeed conditions the control system including the governor 114 will detect the overspeed, connect port 111 and pump outlet 107 with Adrain and unblock the lfeathered position.

. pump 112. The friction of gears 100 and 102 is suicient to cause the gear 102 to rotate with respect to the gear 108 in a direction opposite to the propeller rotation. This motion transmitted through the low ratio gearing 98, 100 and 102 will rotate the valve member 40 tand the threads formed on the outside thereof in a direction to advance the member 40 toward the left or outboard end of the propeller. This movement of the control valve member 40 will admit hydraulic pressure tiuid to the ports 72 and the high pitch chambers 34 and 50 and connect port 74 and low pitch chamber 32 with the drain line 70 which will move the cylinder 26 toward ythe right or inboard and thus move the blades to a higher pitch. The inboard motion of the cylinder 26 and the nut 94 occurs at the same rate as the lead of the -screw threads 96. The maximum forward displacement of the valve member 40 is limited to the valve opening required to move the cylinder 26 to the maximum high pitch blade rate. As the member 40 moves forward the clearance between the upstan-ding flange 116 and the bearing race 122 is reduced. This clearance is greater than the motion required to saturate the control valve in the high pitch direction. Therefore, as long as the hydraulic system operates normally the thrust bearing 120 will not interfere with the operation of the control system.

The motion of the blades towards increased pitch will decrease the propeller speed until the on speed condition is reached. The propeller control including the governor 114 will then stop the rotation of the input gear 102 with respect to the gear 106 and the blades will remain fixed as described for the on speed case.

During under speed condition the propeller control mechanism acts in the opposite sense to that described above for the over speed case and reduces the propeller pitch. The governor 114 will introduce oil under pressure from pump 115 into the pump mechanism 112 and pump outlet 107 and drive the pump as a motor so as to cause the gear 104 to drive the gear 102 faster than the rotation of the shaft 12 so as to move the valve member 40 inboard and connect the chambers 34 and 50 with the drain lines 70 and the chamber 32 with the pressure line 38.

l The axial motion of the valve member 40 required for normal propeller control is limited t-o the motion required to actuate the control valve to high pitch in one direction and to actuate the control valve to low pitch in the other direction. The clearance between the flange 116 and the thrust bearing race 122 and roller 120 is always maintained at a small value. This clearance represents a blade angle change of less than 1. The blade reaction forces including the centrifugal twisting moments act in a direction to move the cylinder 26 in the low pitch direction and therefore the nut 94 and the valve member 40 and its flange 116 are always maintained in a'position to lock the hydraulic pitch change mechanism in the event of a loss of hydraulic power. It should be noted that the nut 94, the screw thread 96, the valve member 40, the flange 116 and the thrust bearing 120 represent a completely independent load path cap-able of supporting the blade loads and electively lock the blade pitch. These elements .are not subjected to fatigue loads and therefore repre-sent an extremely reliable load path.

Normal feathering is accomplished in a conventional manner such las by biasing governor 114 to .an overspeed condition by.raising governor Valve 121 manually by operation of the governor control 125 to move the valve member 40 to the left as explained in the overspeed condition and using the hydraulic pitch change system to continue operation of the increased pitch up to the Feathering may also be accomplished by the mechanical system alone by rst biasing 4the governor as in normal feathering and then actuating the mechanical pitch change mechanism. A loss of hydraulic power either accidentally or intentionally will bring the thrust face of the flange 116 into contact with the thrust bearing race 122 and thrust bearing 120. The race 122 is driven through the gear reduction unit 128 by applying the brake 138 to the flange 136 as long as the propeller is windmilling or the shaft 12 is rotated. The power required to turn the flange 116 and increase the propeller pitch comes from the rotational energy of the propeller. The rotation of the race member 122 by rotation of the shaft 12 with the brake 138 applied will be in a direction to turn the valve member 40 and the screw threads 96 thereon in a direction to force the nut 94 and with it the cylinder 26 and the yoke 46 to the right and move the blades toward the feathered position. The travel of the nut 94 is suicient to allow the blades to exceed the full feathered position by a few degrees. At this angle the aerodynamic forces on the blade reverse and turn the propeller in the opposite direction or backwards. In this position the ange 116 is held in frictional engagement with the race 122 by the Belleville springs 140 so that reverse rotation and the springs 140 will bring the blades back toward the zero feather angle. Any further rotation of the propeller causes the blades to seek the aerodynamic zero feather angle. In order to prevent the feather system from ove-rshooting the feather position by la large amount, a stop 142 is provided on the nut 94 for contact with the abutment 144 on the rotatable member 40. As this stop is engaged, slippage must occur in the mechanical drive of the flange 116 and this occurs along the friction faces between the flange 116 and the bearing race 122.

It is to be understood that the invention is not to be limited to the specific embodiments herein illustrated and described, but may be used in other ways without departure from the spirit and that various changes can be made which would come within the scope of the invention which is limited only by the appended claims.

We claim:

1. Pitch lock means for .a controllable pitch propeller having blades, a blade supporting hub and a pitch changing motor connected to said blades, comprising a control member lfor -said motor having a linearly `movable portion, means, including 'a first connection and a second connection arranged -in series and connecting said blades with said movable por-tion, said first connection including means transforming pitch changi-ng movements of said blades -into bod-ily linear movement .of said second connection and said movable portion as a unit, said second connection including two relatively `movable parts, means, including pitch contr-ol mechanism, 'for relatively adjust- Iing said parts `for changing the relation of the blade pitch and the linear position of said movable portion, said movable portion having a neutral position xed with respect to said hub and having a relatively small linear control movement to one side of said neutral position for controlling energization of said motor, positive mechanical stop means co-acting with said movable portion and blocking linear movement of said movable portion by said blades and thus blocking blade induced pitch change upon failure of said member to energize said motor within said relatively small control movement, and thus provide a pitch lock for said blades.

2. Pitch lock means as claimed in claim 1 `in which said stop means is an abutment iixed with respect to said hub and located in the path of movement of said movable portion by said blades.

3. Pitch lock means as claimed in claim 1 'in which the tirs-t connection is a form of cam Iand roller and the sec- -ond connection is Iformed Vof mat-ed helical or screw threaded members having an axis extending in the direction of said linear movement, one of said helical members lbeing fixed with respect to said mot-or and said motor being fixed against rotation relative to said blade support.

. :4. Pitch lock means as claimed in claim 1 in which said stop means deiines `a limited position of said portion, and Iin which said means adjusting said connecting means changes the relation between the pitch of said blades 'and said vstop llimited position of said movable portion.

5. Pitch lock means as claimed in claim 4 in which said movable portion is mounted for linear movement along an axis by said blades and -said second `connection comprises a helical connection extending in the direction of said axis.

6. Pitch lock means as claimed in claim V1 in which :said motor is a hydraulically actuated motor and said control member is a valve controlling the ow of fluid to said motor and having :a portion xed with respect to said hub cooperating with said movable portion.

7. Pitch lock means as -claimed in claim 6 in which said valve movable portion is movable along an axis for control operation and is rotatable about said vaxis and said connecting means comprises a helical connection adjustable by rotation of said movable portion, said helical connection having one port-ion fixed IWith respect to said motor.

8. Propeller pitch changing mechanism for a propeller having blades and a bla-de support, comprising a pitch changing motor having a translatable part connected with said blades, control means for said motor including a control memb-er, mean-s connecting said member Iwith said motor part including a threaded connection, said connection having one lthreaded portion -xed iwi-th respect to said motor part and the other threaded portion fixed with respect to said control member, said motor part translating said member bodily directly `with translation of said part, `said member being rotatable through said threaded connection with respect to and independent of said part, said threaded connection causing translation of said lmember relative to said part upon rotation of said member independent of part, -said control means including an element fixed with respect to said blade support and cooperating fwith said control member and controlling the energization of said motor by translation of said member relative to said xed element and forming with said member a follow up control actuated by said motor to deenergize said motor.

A9. In a propeller as claimed in claim 8 in which the motor is hydraulically actuated and the control member Iis a portion of a valve connected with the motor :by hydraulic lines and located in the blade support, means external of said .support for moving said control member in said support to control energization of said motor.

10. A propeller as claimed in claim 8 in Which the motor is hydraulically actuated and the translatable control member is a valve ymember iforming a portion of a control valve means 'for moving said valve member to control energization `of said motor including iirst means for rotating said valve member and actuating said threaded connection to translate said valve member and other means for mechanically actuating said valve member including mean-s yfor rotating said valve member and actuating said threaded connection 'for translating said valve member and .means for limiting translating movement of said valve with respect to said blade support so that rotation of said Valve member with respect Ito said motor part by said other means Will mechanically move the propeller blades to cha-nge their pitch upon failure of said valve member to energize said motor.

11. Mechanism as claimed in claim 10 including governor controlled means actuating said iirst means hor rotating said valve member.

12. Pitch changing means `for a propeller having blades, means supporting said blades for pitch changing movement, and a pitch changing motor connected to .said blades comprising a control member tor said motor, means connecting said member with said blades and translating said member by pitch change of said blades, means changing the effective length of said connecting means and means holding said member against translation, and changing the blade pitch independent of pitch change by said motor by changing the effective length of said connecting means.

13. Pitch changing means for a propeller having blades, means supporting said blades for pitch changing movement, and a pitch -changing motor connected to said blad-es, comprising a control member 4for said motor, means connecting said member `with said blad-es and moving said member iby pitch change of said blades, stop means limiting movement of said member by said blades, said connecting means including an adjustable connection operable to relatively move said blade pitch posi-tion and said member .and means for operating Isaid adjustable connection with said member positioned by said stop means to change the pitch of said blades.

14. .Pitch changing means as claimed in claim 13 in which said member is threaded and said adjustable conn-ection comprises a nut connected to said blades mating with threads on said member an-d said means -for operating comprises means `for rota-ting said member and threads relative to said nut.

15. Pitch changing means as claimed in claim 13 in which said stop means includes a iirst bearing race secured to said supporting means and a second bearing race coopera-ting with said first race and having a friction surface, a cooperating friction surface carried by said member and movable by said blades and member `into engagement with said race friction surface and .said means for operating comprises gear reduction means connecting said second race with means holding one end `of the gear train of said gear reduction means against rotation While said propeller is rotating to rot-ate said second race :and said member with respect to said nut and said supporting means.

16. In a controllable pit-ch propeller having blades and a pitch changing motor connected with said blades, a movable control member having a null position and an energizing position a-nd controlling energization of said motor, means connecting said mem-ber Iwith said blades returning said member tonull position incident to movement of said blades by said motor, stop means -in the path of movement of said member vlimiting movement `of said member by said blades, means moving said member relative to said blades while in contact with said `sto-p means and thereby moving said blades to change their pitch independent of said motor.

17. In combination, a hub and shaft ro-tatabl-e as a unit, propeller blades supported by said hub for pitch changing movement, a hydraulic motor connected ywith said blades for imparting pitch changing movement to said blades, means for introducing hyd-raulic uid under pressure to said motor, means controlling the flo-W of hydraulic fluid to said motor comprising valve means having one portion fixed with respect to said hub and another portion movable with respect to said fixed portion and having a null position holding said mot-or stationary yand a position to one side of said null position directing iluid to said motor, means, including mated helical members, mechanically connecting .said movable valve portion with said motor for movement by said motor, means, including means rotating one helical member with respect -tothe other and moving said movable portion to said uiddirecting position, said motor returning said movable portion to null position, mechanical stop means limiting movement with respect to -said fixed portion and said hub, `of said movable portion by said motor and additional means for rotating said one helical member with respect to the other upon yfailure of hydraulic pressure fluid to maintain said movable .member again-st said stop means and utilize said helical members to'mechanically move said motor and change the propeller pitch. l

d8. A propeller having a hub, blades supported by said hub for pitch changing movement, a pitch changing motor connected with said blades and means for energizing said motor including control meals connected with said motor and controlling energization of said motor, means including a screw thread connection mechanically connecting said control means and said blades and means mechanically rotating said control means and utilizing said screw thread connection to mechanically change the propeller pitch upon failure of said motor.

19. A hub and a shaft rotatable as a unit, propeller blades supported by said hub, a hydraulic motor rotatable with said hub comprising Ia piston fixed with respect to said hub anda cylinder surrounding said piston and axially movable thereon, means connecting .said cylinder with said blades for imparting pitch -changing movement to said blades upon axial movement of said cylinder, means tor introducing hydraulic lluid under pressure to said motor for energizing .said motor for moving said cylinder in opposite axial directions, means controlling .the ilow of hydraulic tiuid to and @trom said motor .for controlling the energization thereof comprising valve means including one portion fixed with resp-ect to said hub and another portion movable with respect to said -xed portion `and having a null position for controlling .fluid flow and holding .said motor stationary .and positions on either side o-f said null position for directing fluid to and energizing said motor and moving .said motor .in `one direction or the other, means, including mated helical members, mechanically connecting said movable control portion with said movable cylinder of said motor for imparting movement of said cylinder and lblades to said movable portion to restore said movable portion to its null position, means, including means rotating one helical member with respect to the other helical member yfor moving said -movable portion with respect to said motor and blades to change the rel-ation between the blade pitch and said null position, mechanical stop means, including a cooperating thrust bearing secured to said hub :and a thrust ange secured .to said movable portion mechanically limiting movement of said movable portion by centrifugal twisting moments ot said blades throughout the propeller pitch .range to substantially the distance from said null position to the fully open position of said movable portion, said mov- `able porti-on operable in conjunction with said .stop means lto lock the propel-ler blades against pitch reduction upon tfailure of said motor or its controls, .drive means for rotating said movable portion including a reduction gear connected with one portion of said thrust bearing and Ifriction .drive connection members including `a lfrictional connection between said one bearing portion and .said thrust ilange and means holding one .portion of said reduction gear against rotation while .said shaft is rotating -for r-otating said mov-able portion, rotation of said movable portion rotating 4one helical member relative to the other helical member, movement of said movable portion limited by said stop means so that rotation of said movable member by said drive means will `feather the propeller blades, `and spring means assisting centrifugal twisting moments in holding said thrust flange against said thrust bearing and said friction drive con-nection members in frictional engagement.

20. In combination, in a controllable pitch propeller, propeller blad-es, a hydraulically actuated pitch changing motor operatively connected to said blades, control means for said motor operatively hydraulically connected to said motor, means mechanically connecting said control means to .said blades, means actuating said control means :to hydraulically actuate said motor, and other means actuating said contr-ol means including mean-s manually applying force to said control means and through said cont-rol means manually applying force to said blades. to mechanically change the propeller pitch.

21. In a controllable pitch propeller as claimed in claim 16 spring means urging said member into contact with said stopmeans.

22. A combination as claimed in claim 17 in which said means for rotating said one helical member with respect to the other and moving said movable portion to said fluid directing position includes governor control means Iand said additional means `for rotating said one :helical member includes manually control means mechanically rotating said member.

23. A combination as claimed in claim 17 in which said mated helical members includes one member rotatably mounted with respect to the other member and the other member is Xed with respect to said motor.

24. In a controllable pitch propeller having blades and a blade supporting hub, a pitch changing motor connected to said blades including a motor having a part translatable with pitch changing movement of said blades and xed against rotation with respect to said support, a translatable and rotatable control member for .said motor carried by said hub and means mechanically connecting said motor part and baldes with .said rotatable control member tor bodily translating said member .with said motor part and rotatably connecting said mot-or part with said member for relative translation of said member and said motor part and blades by rotation of said member with respect to said motor part, governor controlled means rotating .said member relative to said blade support to translate said member and energize said motor, other means rotating said member relative to said blade support including means holding said member against translation with respect to said support while rotating said member and thereby translating said motor part .and changing the pitch of said blades.

FOREIGN PATENTS 882,41' 1l/6.1\ Great Britain.

MARK NEWMAN, Primary Examiner.

I ULIUS E. WEST, Examiner. 

20. IN COMBINATION, IN A CONTROLLABLE PITCH PROPELLER, PROPELLER BLADES, A HYDRAULICALLY ACTUATED PITCH CHANGING MOTOR OPERATIVELY CONNECTED TO SAID BLADES, CONTROL MEANS FOR SAID MOTOR OPERATIVELY HYDRAULICALLY CONNECTED TO SAID MOTOR, MEANS MECHANICALLY CONNECTING SAID CONTROL MEANS TO SAID BLADES, MEANS ACTUATING SAID CONTROL MEANS TO HYDRAULICALLY ACTUATE SAID MOTOR, AND OTHER MEANS ACTUATING SAID CONTROL MEANS INCLUDING MEANS MANUALLY APPLYING FORCE TO SAID CONTROL MEANS AND THROUGH SAID CONTROL MEANS MANUALLY APPLYING FORCE TO SAID BLADES TO MECHANICALLY CHANGE THE PROPELLER PITCH. 